feat(C-API): C API now can use multi-zone solver

C api has been brought back up to support and can use paraellization along with multi zone solver

src/extern/include/gridfire/extern/gridfire_context.h

@@ -7,19 +7,32 @@
 #include <memory>
 #include <vector>
 
-struct GridFireContext {
+enum class GFContextType {
+    POINT,
+    GRID
+};
+
+struct GFContext {
+    virtual ~GFContext() = default;
+
     std::unique_ptr<gridfire::policy::NetworkPolicy> policy;
-    gridfire::engine::DynamicEngine* engine;
-    std::unique_ptr<gridfire::solver::DynamicNetworkSolverStrategy> solver;
-
+    const gridfire::engine::DynamicEngine* engine;
+    std::unique_ptr<gridfire::engine::scratch::StateBlob> engine_ctx;
     std::vector<fourdst::atomic::Species> speciesList;
-    fourdst::composition::Composition working_comp;
 
-    void init_species_map(const std::vector<std::string>& species_names);
-    void init_engine_from_policy(const std::string& policy_name, const double *abundances, size_t num_species);
-    void init_solver_from_engine(const std::string& solver_name);
+    virtual void init_species_map(const std::vector<std::string>& species_names);
+    virtual void init_engine_from_policy(const std::string& policy_name, const double *abundances, size_t num_species);
+    virtual void init_solver_from_engine() = 0;
 
-    void init_composition_from_abundance_vector(const double* abundances, size_t num_species);
+    fourdst::composition::Composition init_composition_from_abundance_vector(const std::vector<double> &abundances, size_t num_species) const;
+    std::string last_error;
+};
+
+struct GFPointContext final: GFContext{
+    std::unique_ptr<gridfire::solver::SingleZoneDynamicNetworkSolver> solver;
+    std::unique_ptr<gridfire::solver::SolverContextBase> solver_ctx;
+
+    void init_solver_from_engine() override;
 
     int evolve(
         const double* Y_in,
@@ -35,9 +48,45 @@ struct GridFireContext {
         double& specific_neutrino_energy_loss,
         double& specific_neutrino_flux,
         double& mass_lost
-    );
+    ) const;
 
-    std::string last_error;
 };
 
+struct GFGridContext final : GFContext {
+    std::unique_ptr<gridfire::solver::SingleZoneDynamicNetworkSolver> local_solver;
+    std::unique_ptr<gridfire::solver::MultiZoneDynamicNetworkSolver> solver;
+    std::unique_ptr<gridfire::solver::SolverContextBase> solver_ctx;
+
+    void init_solver_from_engine() override;
+
+    size_t zones;
+
+    void set_zones(const size_t num_zones) {
+        zones = num_zones;
+    }
+
+    [[nodiscard]] size_t get_zones() const {
+        return zones;
+    }
+
+    int evolve(
+        const double* Y_in,
+        size_t num_species,
+        const double* T,
+        const double* rho,
+        double tMax,
+        double dt0,
+        double* Y_out,
+        double* energy_out,
+        double* dEps_dT,
+        double* dEps_dRho,
+        double* specific_neutrino_energy_loss,
+        double* specific_neutrino_flux,
+        double* mass_lost
+    ) const;
+
+};
+
+std::unique_ptr<GFContext> make_gf_context(const GFContextType& type);
+
 #endif

src/extern/include/gridfire/extern/gridfire_extern.h

@@ -6,6 +6,12 @@
 #ifdef __cplusplus
 extern "C" {
 #endif
+    enum GF_TYPE {
+        SINGLE_ZONE = 0,
+        MULTI_ZONE = 1
+    };
+
+
     enum FDSSE_ERROR_CODES {
         FDSSE_NON_4DSTAR_ERROR = -102,
         FDSSE_UNKNOWN_ERROR = -101,
@@ -54,37 +60,49 @@ extern "C" {
         GF_DEBUG_ERROR = 30,
 
         GF_GRIDFIRE_ERROR = 31,
+        GF_UNINITIALIZED_INPUT_MEMORY_ERROR = 32,
+        GF_UNINITIALIZED_OUTPUT_MEMORY_ERROR = 33,
+
+        GF_INVALID_NUM_SPECIES = 34,
+
+        GF_INVALID_TIMESTEPS = 35,
+        GF_UNKNOWN_FREE_TYPE = 36,
+
+        GF_INVALID_TYPE = 37,
     };
 
     char* gf_get_last_error_message(void* ptr);
 
     char* gf_error_code_to_string(int error_code);
 
-    void* gf_init();
+    void* gf_init(const enum GF_TYPE type);
 
-    void gf_free(void* ctx);
+    int gf_free(const enum GF_TYPE type, void *ctx);
+
+    int gf_set_num_zones(const enum GF_TYPE type, void* ptr, const size_t num_zones);
 
     int gf_register_species(void* ptr, const int num_species, const char** species_names);
 
     int gf_construct_engine_from_policy(void* ptr, const char* policy_name, const double *abundances, size_t num_species);
 
-    int gf_construct_solver_from_engine(void* ptr, const char* solver_name);
+    int gf_construct_solver_from_engine(void* ptr);
 
     int gf_evolve(
+        enum GF_TYPE type,
         void* ptr,
-        const double* Y_in,
+        const void* Y_in,
         size_t num_species,
-        double T,
-        double rho,
+        const void* T,
+        const void* rho,
         double tMax,
         double dt0,
-        double* Y_out,
-        double* energy_out,
-        double* dEps_dT,
-        double* dEps_dRho,
-        double* specific_neutrino_energy_loss,
-        double* specific_neutrino_flux,
-        double* mass_lost
+        void* Y_out,
+        void* energy_out,
+        void* dEps_dT,
+        void* dEps_dRho,
+        void* specific_neutrino_energy_loss,
+        void* specific_neutrino_flux,
+        void* mass_lost
     );
 
 #ifdef __cplusplus

src/extern/lib/gridfire_context.cpp

@@ -3,11 +3,10 @@
 #include "fourdst/atomic/species.h"
 
 #include "fourdst/composition/exceptions/exceptions_composition.h"
+#include "gridfire/exceptions/error_policy.h"
+#include "gridfire/utils/logging.h"
 
-void GridFireContext::init_species_map(const std::vector<std::string> &species_names) {
-    for (const auto& name: species_names) {
-        working_comp.registerSymbol(name);
-    }
+void GFContext::init_species_map(const std::vector<std::string> &species_names) {
     this->speciesList.clear();
     this->speciesList.reserve(species_names.size());
 
@@ -24,8 +23,9 @@ void GridFireContext::init_species_map(const std::vector<std::string> &species_n
 
 }
 
-void GridFireContext::init_engine_from_policy(const std::string &policy_name, const double *abundances, const size_t num_species) {
-    init_composition_from_abundance_vector(abundances, num_species);
+void GFContext::init_engine_from_policy(const std::string &policy_name, const double *abundances, const size_t num_species) {
+    const std::vector<double> Y_scratch(abundances, abundances + num_species);
+    fourdst::composition::Composition comp = init_composition_from_abundance_vector(Y_scratch, num_species);
 
     enum class EnginePolicy {
         MAIN_SEQUENCE_POLICY
@@ -47,71 +47,53 @@ void GridFireContext::init_engine_from_policy(const std::string &policy_name, co
 
     switch (engine_map.at(policy_name)) {
         case EnginePolicy::MAIN_SEQUENCE_POLICY: {
-            this->policy = std::make_unique<gridfire::policy::MainSequencePolicy>(this->working_comp);
-            this->engine = &policy->construct();
+            this->policy = std::make_unique<gridfire::policy::MainSequencePolicy>(comp);
+            const auto& [e, ctx] = policy->construct();
+            this->engine = &e;
+            this->engine_ctx = ctx->clone_structure();
+
             break;
         }
         default:
             throw gridfire::exceptions::PolicyError(
-                "Unhandled engine policy in GridFireContext::init_engine_from_policy"
+                "Unhandled engine policy in GFPointContext::init_engine_from_policy"
             );
     }
 
 
 }
 
-void GridFireContext::init_solver_from_engine(const std::string &solver_name) {
-    enum class SolverType {
-        CVODE
-    };
-
-    static const std::unordered_map<std::string, SolverType> solver_map = {
-        {"CVODE", SolverType::CVODE}
-    };
-
-    if (!solver_map.contains(solver_name)) {
-        throw gridfire::exceptions::SolverError(
-            std::format(
-                "Solver {} is not recognized. Valid solvers are: {}",
-                solver_name,
-                gridfire::utils::iterable_to_delimited_string(solver_map, ", ", [](const auto& pair){ return pair.first; })
-            )
-        );
-    }
-
-    switch (solver_map.at(solver_name)) {
-        case SolverType::CVODE: {
-            this->solver = std::make_unique<gridfire::solver::CVODESolverStrategy>(*this->engine);
-            break;
-        }
-        default:
-            throw gridfire::exceptions::SolverError(
-                "Unhandled solver type in GridFireContext::init_solver_from_engine"
-            );
-    }
-
-}
-
-void GridFireContext::init_composition_from_abundance_vector(const double *abundances, size_t num_species) {
+fourdst::composition::Composition GFContext::init_composition_from_abundance_vector(const std::vector<double> &abundances, size_t num_species) const {
     if (num_species == 0) {
         throw fourdst::composition::exceptions::InvalidCompositionError("Cannot initialize composition with zero species.");
     }
-    if (num_species != working_comp.size()) {
+    if (num_species != speciesList.size()) {
         throw fourdst::composition::exceptions::InvalidCompositionError(
             std::format(
                 "Number of species provided ({}) does not match the registered species count ({}).",
                 num_species,
-                working_comp.size()
+                speciesList.size()
             )
         );
     }
 
+    fourdst::composition::Composition comp;
     for (size_t i = 0; i < num_species; i++) {
-        this->working_comp.setMolarAbundance(this->speciesList[i], abundances[i]);
+        comp.registerSpecies(this->speciesList[i]);
+        comp.setMolarAbundance(this->speciesList[i], abundances[i]);
     }
+
+    return comp;
 }
 
-int GridFireContext::evolve(
+
+void GFPointContext::init_solver_from_engine() {
+    this->solver = std::make_unique<gridfire::solver::PointSolver>(*this->engine);
+    this->solver_ctx = std::make_unique<gridfire::solver::PointSolverContext>(*engine_ctx);
+}
+
+
+int GFPointContext::evolve(
     const double* Y_in,
     const size_t num_species,
     const double T,
@@ -125,17 +107,19 @@ int GridFireContext::evolve(
     double& specific_neutrino_energy_loss,
     double& specific_neutrino_flux,
     double& mass_lost
-) {
-    init_composition_from_abundance_vector(Y_in, num_species);
+) const {
+
+    const std::vector<double> Y_scratch(Y_in, Y_in + num_species);
+    const fourdst::composition::Composition comp = init_composition_from_abundance_vector(Y_scratch, num_species);
 
     gridfire::NetIn netIn;
     netIn.temperature = T;
     netIn.density = rho;
     netIn.dt0 = dt0;
     netIn.tMax = tMax;
-    netIn.composition = this->working_comp;
+    netIn.composition = comp;
 
-    const gridfire::NetOut result = this->solver->evaluate(netIn);
+    const gridfire::NetOut result = this->solver->evaluate(*solver_ctx, netIn);
 
     energy_out = result.energy;
     dEps_dT  = result.dEps_dT;
@@ -159,3 +143,99 @@ int GridFireContext::evolve(
 
     return 0;
 }
+
+void GFGridContext::init_solver_from_engine() {
+    this->local_solver = std::make_unique<gridfire::solver::PointSolver>(*this->engine);
+    this->solver = std::make_unique<gridfire::solver::GridSolver>(*this->engine, *this->local_solver);
+    this->solver_ctx = std::make_unique<gridfire::solver::GridSolverContext>(*engine_ctx);
+}
+
+int GFGridContext::evolve(
+    const double* Y_in,
+    size_t num_species,
+    const double *T,
+    const double *rho,
+    double tMax,
+    double dt0,
+    double *Y_out,
+    double *energy_out,
+    double *dEps_dT,
+    double *dEps_dRho,
+    double *specific_neutrino_energy_loss,
+    double *specific_neutrino_flux,
+    double *mass_lost
+) const {
+    if (this->get_zones() == 0) {
+        throw gridfire::exceptions::GridFireError("GFGridContext has zero zones configured for evolution.");
+    }
+
+    if (Y_in == nullptr || T == nullptr || rho == nullptr) {
+        throw gridfire::exceptions::GridFireError("Input abundance, temperature, or density pointers are null.");
+    }
+
+    if (Y_out == nullptr) {
+        throw gridfire::exceptions::GridFireError("Output abundance pointer is null.");
+    }
+
+    std::vector<fourdst::composition::Composition> zone_compositions;
+
+    zone_compositions.reserve(this->get_zones());
+
+    std::vector<double> Y_scratch;
+    Y_scratch.resize(num_species);
+
+    for (size_t i = 0; i < this->get_zones(); ++i) {
+        for (size_t j = 0; j < num_species; ++j) {
+            Y_scratch[j] = Y_in[i * num_species + j];
+        }
+        zone_compositions.push_back(init_composition_from_abundance_vector(Y_scratch, num_species));
+    }
+
+    std::vector<gridfire::NetIn> netIns;
+    netIns.reserve(this->get_zones());
+    for (size_t i = 0; i < this->get_zones(); ++i) {
+        gridfire::NetIn netIn;
+        netIn.temperature = T[i];
+        netIn.density = rho[i];
+        netIn.dt0 = dt0;
+        netIn.tMax = tMax;
+        netIn.composition = zone_compositions[i];
+        netIns.push_back(netIn);
+    }
+
+    std::vector<gridfire::NetOut> results = this->solver->evaluate(*this->solver_ctx, netIns);
+
+    for (size_t zone_idx = 0; zone_idx < this->get_zones(); ++zone_idx) {
+        const gridfire::NetOut& netOut = results[zone_idx];
+        energy_out[zone_idx] = netOut.energy;
+        dEps_dT[zone_idx] = netOut.dEps_dT;;
+        dEps_dRho[zone_idx] = netOut.dEps_dRho;
+        specific_neutrino_energy_loss[zone_idx] = netOut.specific_neutrino_energy_loss;
+        specific_neutrino_flux[zone_idx] = netOut.specific_neutrino_flux;
+
+        std::set<fourdst::atomic::Species> seen_species;
+        for (size_t i = 0; i < num_species; ++i) {
+            fourdst::atomic::Species species = this->speciesList[i];
+            Y_out[zone_idx * num_species + i] = netOut.composition.getMolarAbundance(species);
+            seen_species.insert(species);
+        }
+        mass_lost[zone_idx] = 0.0;
+        for (const auto& species : netOut.composition.getRegisteredSpecies()) {
+            if (!seen_species.contains(species)) {
+                mass_lost[zone_idx] += species.mass() * netOut.composition.getMolarAbundance(species);
+            }
+        }
+    }
+    return 0;
+}
+
+std::unique_ptr<GFContext> make_gf_context(const GFContextType &type) {
+    switch (type) {
+        case GFContextType::POINT:
+            return std::make_unique<GFPointContext>();
+        case GFContextType::GRID:
+            return std::make_unique<GFGridContext>();
+        default:
+            throw gridfire::exceptions::GridFireError("Unhandled GFContextType in make_gf_context");
+    }
+}

src/extern/lib/gridfire_extern.cpp

@@ -3,120 +3,18 @@
 #include "gridfire/extern/gridfire_context.h"
 #include "gridfire/extern/gridfire_extern.h"
 
-extern "C" {
-    void* gf_init() {
-        return new GridFireContext();
-    }
+namespace {
 
-    void gf_free(void* ctx) {
-        delete static_cast<GridFireContext*>(ctx);
-    }
+    template<typename T>
+    concept ErrorTrackable = requires(T a) {
+        { a.last_error } -> std::convertible_to<std::string>;
+    };
 
-    int gf_register_species(void* ptr, const int num_species, const char** species_names) {
-        auto* ctx = static_cast<GridFireContext*>(ptr);
+    template <ErrorTrackable Context, typename Func>
+    int execute_guarded(Context* ctx, Func&& action) {
         try {
-            std::vector<std::string> names;
-            for(int i=0; i<num_species; ++i) {
-                names.emplace_back(species_names[i]);
-            }
-            ctx->init_species_map(names);
-            return FDSSE_SUCCESS;
-        } catch (const fourdst::composition::exceptions::UnknownSymbolError& e) {
-            ctx->last_error = e.what();
-            return FDSSE_UNKNOWN_SYMBOL_ERROR;
-        } catch (const fourdst::composition::exceptions::SpeciesError& e) {
-            ctx->last_error = e.what();
-            return FDSSE_SPECIES_ERROR;
-        } catch (const std::exception& e) {
-            ctx->last_error = e.what();
-            return FDSSE_NON_4DSTAR_ERROR;
-        } catch (...) {
-            ctx->last_error = "Unknown error occurred during species registration.";
-            return FDSSE_UNKNOWN_ERROR;
-        }
-    }
+            const int result = action();
 
-    int gf_construct_engine_from_policy(
-        void* ptr,
-        const char* policy_name,
-        const double *abundances,
-        const size_t num_species
-    ) {
-        auto* ctx = static_cast<GridFireContext*>(ptr);
-        try {
-            ctx->init_engine_from_policy(std::string(policy_name), abundances, num_species);
-            return GF_SUCCESS;
-        } catch (const gridfire::exceptions::MissingBaseReactionError& e) {
-            ctx->last_error = e.what();
-            return GF_MISSING_BASE_REACTION_ERROR;
-        } catch (const gridfire::exceptions::MissingSeedSpeciesError& e) {
-            ctx->last_error = e.what();
-            return GF_MISSING_SEED_SPECIES_ERROR;
-        }  catch (const gridfire::exceptions::MissingKeyReactionError& e) {
-            ctx->last_error = e.what();
-            return GF_MISSING_KEY_REACTION_ERROR;
-        } catch (const gridfire::exceptions::PolicyError& e) {
-            ctx->last_error = e.what();
-            return GF_POLICY_ERROR;
-        } catch (std::exception& e) {
-            ctx->last_error = e.what();
-            return GF_NON_GRIDFIRE_ERROR;
-        } catch (...) {
-            ctx->last_error = "Unknown error occurred during engine construction.";
-            return GF_UNKNOWN_ERROR;
-        }
-    }
-
-    int gf_construct_solver_from_engine(
-        void* ptr,
-        const char* solver_name
-    ) {
-        auto* ctx = static_cast<GridFireContext*>(ptr);
-        try {
-            ctx->init_solver_from_engine(std::string(solver_name));
-            return GF_SUCCESS;
-        } catch (std::exception& e) {
-            ctx->last_error = e.what();
-            return GF_NON_GRIDFIRE_ERROR;
-        } catch (...) {
-            ctx->last_error = "Unknown error occurred during solver construction.";
-            return GF_UNKNOWN_ERROR;
-        }
-    }
-
-    int gf_evolve(
-        void* ptr,
-        const double* Y_in,
-        const size_t num_species,
-        const double T,
-        const double rho,
-        const double tMax,
-        const double dt0,
-        double* Y_out,
-        double* energy_out,
-        double* dEps_dT,
-        double* dEps_dRho,
-        double* specific_neutrino_energy_loss,
-        double* specific_neutrino_flux,
-        double* mass_lost
-    ) {
-        auto* ctx = static_cast<GridFireContext*>(ptr);
-        try {
-            const int result = ctx->evolve(
-                Y_in,
-                num_species,
-                T,
-                rho,
-                tMax,
-                dt0,
-                Y_out,
-                *energy_out,
-                *dEps_dT,
-                *dEps_dRho,
-                *specific_neutrino_energy_loss,
-                *specific_neutrino_flux,
-                *mass_lost
-            );
             if (result != 0) {
                 return result;
             }
@@ -211,8 +109,218 @@ extern "C" {
         }
     }
 
+}
+
+extern "C" {
+
+
+    void* gf_init(const enum GF_TYPE type) {
+        if (type == MULTI_ZONE) {
+            return new GFGridContext();
+        }
+        if (type == SINGLE_ZONE) {
+            return new GFPointContext();
+        }
+        return nullptr;
+    }
+
+    int gf_free(const enum GF_TYPE type, void *ctx) {
+        if (!ctx) {
+            return GF_UNINITIALIZED_INPUT_MEMORY_ERROR;
+        }
+        if (type == MULTI_ZONE) {
+            delete static_cast<GFGridContext*>(ctx);
+            return GF_SUCCESS;
+        }
+        if (type == SINGLE_ZONE) {
+            delete static_cast<GFPointContext*>(ctx);
+            return GF_SUCCESS;
+        }
+        return GF_UNKNOWN_FREE_TYPE;
+    }
+
+    int gf_set_num_zones(const enum GF_TYPE type, void* ptr, const size_t num_zones) {
+        if (type != MULTI_ZONE) {
+            return GF_INVALID_TYPE;
+        }
+
+        if (!ptr) {
+            return GF_UNINITIALIZED_INPUT_MEMORY_ERROR;
+        }
+
+        auto* ctx = static_cast<GFGridContext*>(ptr);
+        return execute_guarded(ctx, [&]() {
+            ctx->set_zones(num_zones);
+            return GF_SUCCESS;
+        });
+    }
+
+    int gf_register_species(void* ptr, const int num_species, const char** species_names) {
+        if (num_species < 0) return GF_INVALID_NUM_SPECIES;
+
+        if (num_species == 0) return GF_SUCCESS;
+
+        if (!ptr || !species_names) {
+            return GF_UNINITIALIZED_INPUT_MEMORY_ERROR;
+        }
+
+        for (int i=0; i < num_species; ++i) {
+            if (!species_names[i]) {
+                return GF_UNINITIALIZED_INPUT_MEMORY_ERROR;
+            }
+        }
+
+        auto* ctx = static_cast<GFContext*>(ptr);
+        return execute_guarded(ctx, [&]() {
+           std::vector<std::string> names;
+            for (int i=0; i<num_species; ++i) {
+                names.emplace_back(species_names[i]);
+            }
+            ctx->init_species_map(names);
+            return FDSSE_SUCCESS;
+        });
+    }
+
+    int gf_construct_engine_from_policy(
+        void* ptr,
+        const char* policy_name,
+        const double *abundances,
+        const size_t num_species
+    ) {
+        auto* ctx = static_cast<GFContext*>(ptr);
+        return execute_guarded(ctx, [&]() {
+            ctx->init_engine_from_policy(std::string(policy_name), abundances, num_species);
+            return GF_SUCCESS;
+        });
+    }
+
+    int gf_construct_solver_from_engine(
+        void* ptr
+    ) {
+        auto* ctx = static_cast<GFContext*>(ptr);
+        return execute_guarded(ctx, [&]() {
+            ctx->init_solver_from_engine();
+            return GF_SUCCESS;
+        });
+    }
+
+    int gf_evolve(
+        const enum GF_TYPE type,
+        void* ptr,
+        const void* Y_in,
+        const size_t num_species,
+        const void* T,
+        const void* rho,
+        const double tMax,
+        const double dt0,
+        void* Y_out,
+        void* energy_out,
+        void* dEps_dT,
+        void* dEps_dRho,
+        void* specific_neutrino_energy_loss,
+        void* specific_neutrino_flux,
+        void* mass_lost
+    ) {
+
+        if (!ptr || !Y_in || !T || !rho) {
+            return GF_UNINITIALIZED_INPUT_MEMORY_ERROR;
+        }
+
+        if (!Y_out || !energy_out || !dEps_dT || !dEps_dRho || !specific_neutrino_energy_loss || !specific_neutrino_flux || !mass_lost) {
+            return GF_UNINITIALIZED_OUTPUT_MEMORY_ERROR;
+        }
+
+        if (tMax <= 0 || dt0 <= 0) {
+            return GF_INVALID_TIMESTEPS;
+        }
+
+        if (num_species <= 0) {
+            return GF_INVALID_NUM_SPECIES;
+        }
+
+        switch (type) {
+            case SINGLE_ZONE : {
+                auto* ctx = static_cast<GFPointContext*>(ptr);
+                const auto T_ptr = static_cast<const double*>(T);
+                const auto *rho_ptr = static_cast<const double*>(rho);
+
+                auto* Y_out_local = static_cast<double*>(Y_out);
+                auto* energy_out_local = static_cast<double*>(energy_out);
+                auto* dEps_dT_local = static_cast<double*>(dEps_dT);
+                auto* dEps_dRho_local = static_cast<double*>(dEps_dRho);
+                auto* specific_neutrino_energy_loss_local = static_cast<double*>(specific_neutrino_energy_loss);
+                auto* specific_neutrino_flux_local = static_cast<double*>(specific_neutrino_flux);
+                auto* mass_lost_local = static_cast<double*>(mass_lost);
+
+                return execute_guarded(ctx, [&]() {
+                    return ctx->evolve(
+                        static_cast<const double*>(Y_in),
+                        num_species,
+                        *T_ptr,
+                        *rho_ptr,
+                        tMax,
+                        dt0,
+                        Y_out_local,
+                        *energy_out_local,
+                        *dEps_dT_local,
+                        *dEps_dRho_local,
+                        *specific_neutrino_energy_loss_local,
+                        *specific_neutrino_flux_local,
+                        *mass_lost_local
+                    );
+                });
+            }
+            case MULTI_ZONE : {
+                auto* ctx = static_cast<GFGridContext*>(ptr);
+                const auto *T_ptr = static_cast<const double*>(T);
+                const auto *rho_ptr = static_cast<const double*>(rho);
+
+                auto* Y_out_local = static_cast<double*>(Y_out);
+                auto* energy_out_local = static_cast<double*>(energy_out);
+                auto* dEps_dT_local = static_cast<double*>(dEps_dT);
+                auto* dEps_dRho_local = static_cast<double*>(dEps_dRho);
+                auto* specific_neutrino_energy_loss_local = static_cast<double*>(specific_neutrino_energy_loss);
+                auto* specific_neutrino_flux_local = static_cast<double*>(specific_neutrino_flux);
+                auto* mass_lost_local = static_cast<double*>(mass_lost);
+
+                // for (size_t i = 0; i < ctx->get_zones(); ++i) {
+                //     if (!Y_out_local[i]) {
+                //         std::cerr << "Uninitialized memory for Y_out at zone " << i << std::endl;
+                //         return GF_UNINITIALIZED_OUTPUT_MEMORY_ERROR;
+                //     }
+                // }
+
+                return execute_guarded(ctx, [&]() {
+                    return ctx->evolve(
+                        static_cast<const double*>(Y_in),
+                        num_species,
+                        T_ptr, // T pointer
+                        rho_ptr, // rho pointer
+                        tMax,
+                        dt0,
+                        Y_out_local,
+                        energy_out_local,
+                        dEps_dT_local,
+                        dEps_dRho_local,
+                        specific_neutrino_energy_loss_local,
+                        specific_neutrino_flux_local,
+                        mass_lost_local
+                    );
+                });
+            }
+            default :
+                return GF_UNKNOWN_ERROR;
+        }
+
+
+
+    }
+
     char* gf_get_last_error_message(void* ptr) {
-        const auto* ctx = static_cast<GridFireContext*>(ptr);
+        if (!ptr) {
+            return const_cast<char*>("GF_UNINITIALIZED_INPUT_MEMORY_ERROR");
+        }
+        const auto* ctx = static_cast<GFContext*>(ptr);
         return const_cast<char*>(ctx->last_error.c_str());
     }
 
@@ -278,6 +386,18 @@ extern "C" {
                 return const_cast<char*>("GF_DEBUG_ERROR");
             case GF_GRIDFIRE_ERROR:
                 return const_cast<char*>("GF_GRIDFIRE_ERROR");
+            case GF_UNINITIALIZED_INPUT_MEMORY_ERROR:
+                return const_cast<char*>("GF_UNINITIALIZED_INPUT_MEMORY_ERROR");
+            case GF_UNINITIALIZED_OUTPUT_MEMORY_ERROR:
+                return const_cast<char*>("GF_UNINITIALIZED_OUTPUT_MEMORY_ERROR");
+            case GF_INVALID_NUM_SPECIES:
+                return const_cast<char*>("GF_INVALID_NUM_SPECIES");
+            case GF_INVALID_TIMESTEPS:
+                return const_cast<char*>("GF_INVALID_TIMESTEPS");
+            case GF_UNKNOWN_FREE_TYPE:
+                return const_cast<char*>("GF_UNKNOWN_FREE_TYPE");
+            case GF_INVALID_TYPE:
+                return const_cast<char*>("GF_INVALID_TYPE");
             case FDSSE_NON_4DSTAR_ERROR:
                 return const_cast<char*>("FDSSE_NON_4DSTAR_ERROR");
             case FDSSE_UNKNOWN_ERROR:

tests/extern/C/gridfire_evolve_multi.c

@@ -0,0 +1,123 @@
+#include "gridfire/extern/gridfire_extern.h"
+#include <stdio.h>
+
+#define NUM_SPECIES 8
+#define ZONES 100
+#define ZONE_POLICY MULTI_ZONE
+
+// Define a macro to check return codes
+#define CHECK_RET_CODE(ret, ctx, msg) \
+    if ((ret) != 0 && (ret) != 1) { \
+        printf("Error %s: %s (No. %d) [%s]\n", msg, gf_error_code_to_string(ret), ret, gf_get_last_error_message(ctx)); \
+        gf_free(ZONE_POLICY, ctx); \
+        return 1; \
+    }
+
+int main() {
+    printf("Testing GridFireEvolve Multi\n");
+    printf(" Number of zones: %d\n", ZONES);
+    printf(" Number of species: %d\n", NUM_SPECIES);
+    printf(" Initializing..");
+    void* ctx = gf_init(ZONE_POLICY);
+    printf(" Done.\n");
+    printf(" Setting number of zones to %d..", ZONES);
+    gf_set_num_zones(ZONE_POLICY, ctx, ZONES);
+    printf(" Done.\n");
+
+    const char* species_names[NUM_SPECIES];
+    species_names[0] = "H-1";
+    species_names[1] = "He-3";
+    species_names[2] = "He-4";
+    species_names[3] = "C-12";
+    species_names[4] = "N-14";
+    species_names[5] = "O-16";
+    species_names[6] = "Ne-20";
+    species_names[7] = "Mg-24";
+    const double abundance_root[NUM_SPECIES] = {
+        0.702616602672027,
+        9.74791583949078e-06,
+        0.06895512307276903,
+        0.00025,
+        7.855418029399437e-05,
+        0.0006014411598306529,
+        8.103062886768109e-05,
+        2.151340851063217e-05
+    };
+
+    double abundances[ZONES][NUM_SPECIES];
+    for (size_t zone = 0; zone < ZONES; zone++) {
+        for (size_t i = 0; i < NUM_SPECIES; i++) {
+            abundances[zone][i] = abundance_root[i];
+        }
+    }
+
+    double Temps[ZONES];
+    double Rhos[ZONES];
+
+    for (size_t zone = 0; zone < ZONES; zone++) {
+        Temps[zone] = 1.0e7;
+        Rhos[zone] = 1.5e2;
+    }
+
+    printf(" Registering species...");
+    int ret = gf_register_species(ctx, NUM_SPECIES, species_names);
+    CHECK_RET_CODE(ret, ctx, "SPECIES");
+    printf(" Done.\n");
+
+    printf(" Constructing engine from policy...");
+    ret = gf_construct_engine_from_policy(ctx, "MAIN_SEQUENCE_POLICY", abundance_root, NUM_SPECIES);
+    CHECK_RET_CODE(ret, ctx, "MAIN_SEQUENCE_POLICY");
+    printf(" Done.\n");
+
+    printf(" Constructing solver from engine...");
+    ret = gf_construct_solver_from_engine(ctx);
+    CHECK_RET_CODE(ret, ctx, "CVODE");
+    printf(" Done.\n");
+
+    double Y_out[ZONES][NUM_SPECIES];
+    double energy_out[ZONES];
+    double dEps_dT[ZONES];
+    double dEps_dRho[ZONES];
+    double specific_neutrino_energy_loss[ZONES];
+    double specific_neutrino_flux[ZONES];
+    double mass_lost[ZONES];
+
+    printf(" Evolving...\n");
+    ret = gf_evolve(
+        ZONE_POLICY,
+        ctx,
+        abundances,
+        NUM_SPECIES,
+        Temps,    // Temperature in K
+        Rhos,    // Density in g/cm^3
+        3e17,      // Time step in seconds
+        1e-12,
+        Y_out,
+        energy_out,
+        dEps_dT,
+        dEps_dRho,
+        specific_neutrino_energy_loss,
+        specific_neutrino_flux, &mass_lost
+    );
+    CHECK_RET_CODE(ret, ctx, "EVOLUTION");
+    printf(" Done.\n");
+
+
+    printf("Evolved abundances:\n");
+    for (size_t zone = 0; zone < ZONES; zone++) {
+        printf("=== Zone %zu ===\n", zone);
+        for (size_t i = 0; i < NUM_SPECIES; i++) {
+            printf("  Species %s: %e\n", species_names[i], Y_out[zone][i]);
+        }
+        printf("  Energy output: %e\n", energy_out[zone]);
+        printf("  dEps/dT: %e\n", dEps_dT[zone]);
+        printf("  dEps/dRho: %e\n", dEps_dRho[zone]);
+        printf("  Specific neutrino energy loss: %e\n", specific_neutrino_energy_loss[zone]);
+        printf("  Specific neutrino flux: %e\n", specific_neutrino_flux[zone]);
+        printf("  Mass lost: %e\n", mass_lost[zone]);
+    }
+
+    gf_free(ZONE_POLICY, ctx);
+
+    return 0;
+}

tests/extern/C/gridfire_evolve_single.c

@@ -4,14 +4,14 @@
 
 // Define a macro to check return codes
 #define CHECK_RET_CODE(ret, ctx, msg) \
-    if (ret != 0 && ret != 1) { \
-        printf("Error %s: %s\n", msg, gf_get_last_error_message(ctx)); \
-        gf_free(ctx); \
+    if ((ret) != 0 && (ret) != 1) { \
+        printf("Error %s: %s [%s]\n", msg, gf_get_last_error_message(ctx), gf_error_code_to_string(ret)); \
+        gf_free(SINGLE_ZONE, ctx); \
         return 1; \
     }
 
 int main() {
-    void* ctx = gf_init();
+    void* ctx = gf_init(SINGLE_ZONE);
 
     const char* species_names[NUM_SPECIES];
     species_names[0] = "H-1";
@@ -39,7 +39,7 @@ int main() {
     ret = gf_construct_engine_from_policy(ctx, "MAIN_SEQUENCE_POLICY", abundances, NUM_SPECIES);
     CHECK_RET_CODE(ret, ctx, "MAIN_SEQUENCE_POLICY");
 
-    ret = gf_construct_solver_from_engine(ctx, "CVODE");
+    ret = gf_construct_solver_from_engine(ctx);
     CHECK_RET_CODE(ret, ctx, "CVODE");
 
     double Y_out[NUM_SPECIES];
@@ -50,21 +50,24 @@ int main() {
     double specific_neutrino_flux;
     double mass_lost;
 
+    const double T_in = 1.5e7; // Temperature in K
+    const double rho_in = 1.5e2; // Density in g/cm^3
+
     ret = gf_evolve(
+        SINGLE_ZONE,
         ctx,
         abundances,
         NUM_SPECIES,
-        1.5e7,    // Temperature in K
-        1.5e2,    // Density in g/cm^3
+        &T_in,    // Temperature in K
+        &rho_in,    // Density in g/cm^3
         3e17,      // Time step in seconds
-        1e-12, // Initial time step in seconds
+        1e-12,
         Y_out,
         &energy_out,
         &dEps_dT,
         &dEps_dRho,
         &specific_neutrino_energy_loss,
-        &specific_neutrino_flux,
-        &mass_lost
+        &specific_neutrino_flux, &mass_lost
     );
 
     CHECK_RET_CODE(ret, ctx, "EVOLUTION");
@@ -81,7 +84,7 @@ int main() {
     printf("Specific neutrino flux: %e\n", specific_neutrino_flux);
     printf("Mass lost: %e\n", mass_lost);
 
-    gf_free(ctx);
+    gf_free(SINGLE_ZONE, ctx);
 
     return 0;
 }

tests/extern/C/meson.build

@@ -1,5 +1,11 @@
-executable('test_c_extern', 'gridfire_evolve.c',
+executable('gf_extern_c_single', 'gridfire_evolve_single.c',
   install: false,
   c_args: ['-Wall', '-Wextra'],
   dependencies: [gridfire_extern_dep]
 )
+
+executable('gf_extern_c_multi', 'gridfire_evolve_multi.c',
+           install: false,
+           c_args: ['-Wall', '-Wextra'],
+           dependencies: [gridfire_extern_dep]
+)